Rationalizing polymer swelling and collapse under repulsive to highly attractive cosolvent conditions

TL;DR

This study uses computer simulations and theoretical models to understand how different strengths of interactions between polymers and cosolvents influence polymer swelling and collapse, revealing distinct mechanisms and conditions for each state.

Contribution

It provides a systematic analysis combining simulations and models to explain polymer behavior under various cosolvent interactions, highlighting the role of attraction strength and range.

Findings

Maximal swelling occurs with weakly attractive interactions.

Highly attractive interactions induce collapse with high cosolute density inside.

Collapse mechanisms differ significantly depending on interaction strength.

Abstract

The collapse and swelling behavior of a generic homopolymer is studied using implicit-solvent, explicit-cosolvent Langevin dynamics computer simulations for varying interaction strengths. The systematic investigation reveals that polymer swelling is maximal if both monomer-monomer and monomer-cosolute interactions are weakly attractive. In the most swollen state the cosolute density inside the coil is remarkably bulk-like and homogenous. Highly attractive monomer-cosolute interactions, however, are found to induce a collapse of the chain which, in contrast to the collapsed case induced by purely repulsive cosolvents, exhibits a considerably enhanced cosolute density within the globule. Thus, collapsed states, although appearing similar on a first glance, may result from very different mechanisms with distinct final structural and thermodynamics properties. Two theoretical models, one based on an effective one-component description where the cosolutes have been integrated out, and a fully two-component Flory -- de Gennes like model, support the simulation findings above and serve for interpretation. In particular, the picture is supported that collapse in highly attractive cosolvents is driven by crosslinking-like bridging effects, while the ratio of attraction width to cosolute size plays a critical role behind this mechanism. Only if polymer-cosolute interactions are not too short-ranged swelling effects should be observable. Our findings may be important for the interpretation of the effects of cosolutes on polymer and protein conformational structure, in particular for highly attractive interaction combinations, such as provided by urea, GdmCl, NaI, or NaClO4 near peptide-like moieties.